Enhanced plasticity of mature granule cells reduces survival of newborn neurons in the adult mouse hippocampus.

Felix B Kleine Borgmann, Johannes Gräff, Isabelle M Mansuy, Nicolas Toni, Sebastian Jessberger
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引用次数: 2

Abstract

Dentate granule cells are born throughout life in the mammalian hippocampus. The integration of newborn neurons into the dentate circuit is activity-dependent, and structural data characterizing synapse formation suggested that the survival of adult-born granule cells is regulated by competition for synaptic partners. Here we tested this hypothesis by using a mouse model with genetically enhanced plasticity of mature granule cells through temporally controlled expression of a nuclear inhibitor of protein phosphatase 1 (NIPP1*). Using thymidine analogues and retrovirus-mediated cell labeling, we show that synaptic integration and subsequent survival of newborn neurons is decreased in NIPP1*-expressing mice, suggesting that newborn neurons compete with preexisting granule cells for stable integration. The data presented here provides experimental evidence for a long-standing hypothesis and suggest cellular competition as a key mechanism regulating the integration and survival of newborn granule cells in the adult mammalian hippocampus.

Abstract Image

成熟颗粒细胞可塑性的增强降低了成年小鼠海马新生神经元的存活率。
齿状颗粒细胞在哺乳动物海马中终生生成。新生神经元与齿状回路的整合是活动依赖的,表征突触形成的结构数据表明,成年出生的颗粒细胞的存活受到突触伴侣竞争的调节。本研究通过暂时控制蛋白磷酸酶1核抑制剂(NIPP1*)的表达,利用成熟颗粒细胞遗传增强可塑性的小鼠模型验证了这一假设。通过胸苷类似物和逆转录病毒介导的细胞标记,我们发现NIPP1*表达小鼠的突触整合和新生神经元的后续存活减少,这表明新生神经元与先前存在的颗粒细胞竞争以稳定整合。本研究的数据为一个长期存在的假设提供了实验证据,并表明细胞竞争是调节成年哺乳动物海马新生颗粒细胞整合和存活的关键机制。
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